When lowering temperature, the in vivo circadian clock in cyanobacteria follows and surpasses the in vitro protein clock trough the Hopf bifurcation

I. Mihalcescu, H. Kaji, H. Maruyama, J. Giraud, M. Van-Melle Gateau, B. Houchmandzadeh, H. Ito
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Abstract

The in vivo circadian clock in single cyanobacteria is studied here by time-lapse fluorescence microscopy when the temperature is lowered below 25{\deg}C . We first disentangle the circadian clock behavior from the bacterial cold shock response by identifying a sequence of "death steps" based on cellular indicators. By analyzing only "alive" tracks, we show that the dynamic response of individual oscillatory tracks to a step-down temperature signal is described by a simple Stuart-Landau oscillator model. The same dynamical analysis applied to in vitro data (KaiC phosphorylation level following a temperature step-down) allows for extracting and comparing both clock's responses to a temperature step down. It appears, therefore, that both oscillators go through a similar supercritical Hopf bifurcation. Finally, to quantitatively describe the temperature dependence of the resulting in vivo and in vitro Stuart-Landau parameters $\mu(T)$ and $\omega_c(T)$, we propose two simplified analytical models: temperature-dependent positive feedback or time-delayed negative feedback that is temperature compensated. Our results provide strong constraints for future models and emphasize the importance of studying transitory regimes along temperature effects in circadian systems.
当温度降低时,蓝藻体内的昼夜节律遵循并超越体外蛋白质时钟的霍普夫分岔曲线
本文通过延时荧光显微镜研究了温度降低到25{/deg}C以下时单体蓝藻的体内昼夜节律钟。我们首先根据细胞指标确定了一系列 "死亡步骤",从而将昼夜节律行为与细菌冷休克反应区分开来。通过只分析 "活着的 "轨道,我们发现单个振荡轨道对降温信号的动态响应可以用一个简单的斯图尔特-朗道振荡器模型来描述。对体外数据(温度骤降后的 KaiC 磷酸化水平)进行类似的动力学分析,可以提取和比较两种时钟对温度骤降的响应。因此,两个振荡器似乎都经历了类似的超临界霍普夫分岔。最后,为了定量描述体内和体外斯图尔特-朗道参数 $\mu(T)$ 和 $\omega_c(T)$ 的温度依赖性,我们提出了两个简化的分析模型:温度依赖性正反馈或温度补偿的时间延迟负反馈。我们的结果为未来的模型提供了强有力的约束,并强调了研究昼夜节律系统中温度效应的过渡态的重要性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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